JP2009537718A - Brick and rod system - Google Patents

Abstract

  The invention of the present application provides a system of bricks and rods (4, 5A, 5B) for building walls with high resistance to extreme gravitational forces, lateral forces, and periodic forces. This system allows the construction of a wall consisting of bricks reinforced with skeletons of rods (4, 5A, 5B). The bricks of this system are rectangular blocks with horizontal (1) and vertical protrusions (3) and cavities (2) that allow horizontal and vertical connection between adjacent bricks of the wall. It is. The brick is further perforated with holes (15) that are aligned with the vertically adjacent holes (15) of the wall, thereby providing continuous vertical holes (15) extending across the entire height of the wall. It is formed. The system rod (4, 5A, 5B) penetrates the brick through a continuous hole (15) in the wall.

Description

  The present invention relates to the field of wall construction with bricks connected horizontally and vertically.

  In the field of the present invention, there has been described a wall constructed of bricks with protrusions and cavities connecting horizontally and vertically for the purpose of reducing the amount of adhesive or mortar used. Bricks with protrusions and cavities that connect horizontally and vertically are also aimed at building walls with high lateral strength against uniform and periodic forces due to nature It is also described. However, it reduces the amount of adhesives and mortar used, and also provides a wall that has high lateral stiffness, extreme gravity forces, periodic forces, and high resistance to uniform forces. There is no mention of a brick and rod system for construction.

  In the prior art, protrusions and cavities that result in walls with high resistance to natural, uniform and periodic forces while reducing the amount of adhesive or mortar used by connecting horizontally and vertically. There is a description about construction of a wall body using a brick provided with.

  In particular, Nanayakkara, in Patent Document 1, Patent Document 2, and Patent Document 3, is equipped with a horizontal and vertical connection system, and reduces the amount of mortar used while maintaining a high lateral direction against uniform and periodic forces due to nature. A brick or block is described which results in a wall body having a yield strength of. Patent Document 1 has a continuous geometrical shape having positive and negative complementary geometrical outlines and a continuous vertical cavity, thereby realizing horizontal and vertical connection between adjacent bricks. A brick is described that builds a wall with vertical cavities.

US Pat. No. 6,550,208 US Pat. No. 6,105,330 US Pat. No. 6,578,338

  However, neither the prior art nor the Nanayakara patent mentions bricks or blocks similar to those described in the brick and rod system of the present invention. The brick or block described in the Nanayakara patent has a yin and yang geometric profile, which differs from the brick protrusions and cavities of the present invention. Further, the prior art describes a brick with perforations or holes specifically adapted to the diameter of the rod which has the function of reinforcing the connection formed by the brick protrusions and cavities adjacent to the horizontal and vertical direction of the wall. There is no example. The brick and rod system of the present invention is, for example, a retaining wall, or other type of wall, for high lateral stiffness, extreme gravity forces, periodic forces, and uniform forces. It is possible to construct a wall body such as a wall body having a high yield strength. The brick and rod system of the present invention also provides a flexible connection between horizontally and vertically adjacent bricks for the construction of walls that are less prone to cracking during earthquake motion or earthquakes.

The present invention is a brick and rod system, which is a rectangular three-dimensional brick for wall construction, which defines the horizontal axis X defining the brick length, the brick height Characterized by a vertical axis Y, a brick defined by three orthogonal coordinates X, Y, Z of a horizontal axis Z defining the width of the brick, and a rod,
a. An upper horizontal plane and a lower horizontal plane defined by the X axis and the Z axis;
b. A front vertical plane and a rear vertical plane defined by the Z-axis and the Y-axis;
c. Two vertical sides defined by the X and Y axes;
d. A projecting portion having a rounded convex geometric shape in the X-axis direction provided in the center of the front vertical surface of the brick, the projecting portion being horizontally adjacent by the cavity described in e. A protrusion that is exactly connected to the block and whose base on the front vertical surface of the brick defined in the same direction of the Z-axis is shorter than the maximum diameter of the convex geometry of the protrusion;
e. A symmetric cavity having a concave geometric shape in the X-axis direction provided in the center of the rear vertical surface of the brick, and the cavity is accurately connected to a horizontally adjacent block by a protrusion described in d. A cavity whose opening length on the back vertical plane of the brick defined in the same direction as the Z-axis is shorter than the maximum diameter of the concave geometric shape of the cavity,
f. Two protrusions of cylindrical concave geometry in the Y-axis direction symmetrically arranged in the center of the upper horizontal surface of the brick, wherein the protrusions are vertically adjacent by a cavity described in g And a protrusion having a base diameter of each protrusion on the upper horizontal surface of the brick that is greater than or equal to the diameter of the cylindrical portion of the protrusion;
g. Two hollow portions of cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the lower horizontal surface of the brick, wherein the hollow portions are vertically adjacent by the protrusions described in f And a cavity portion in which the diameter of the opening of each cavity portion on the lower horizontal surface of the brick is equal to or greater than the diameter of the cylindrical portion of the cavity portion,
h. Two vertical cylindrical holes penetrating the brick, the length of the hole in the Y-axis direction being from the top of the convex geometry of the protrusion described in f to the concave geometry of the cavity described in g A continuum that is defined by the top of the geometric shape and extends over the entire height of the wall by aligning the hole and the same hole in the wall vertically with that of the brick that is vertically adjacent in the direction of the vertical axis of the wall A hole forming a vertical hole,
i. Two vertical cylindrical holes penetrating the brick, the length of the hole in the Y-axis direction being defined by the upper horizontal surface of the brick to the lower horizontal surface of the brick, the holes being described in h The holes and the holes of the same diameter as described in j of the bricks adjacent in the vertical direction are aligned in the direction of the vertical axis of the wall body and extend over the entire height of the wall body. A hole having a diameter commensurate with the diameter of the rod so that a continuous vertical hole is formed, the hole being able to be inserted into a continuous hole extending over the entire height of the wall;
j. a vertical cylindrical hole penetrating the protrusion described in d in the Y-axis direction, the length of the hole being defined by the center of the upper horizontal plane of the protrusion to the center of the lower horizontal plane of the protrusion; This hole and a hole of the same diameter described in i of a brick adjacent to the vertical direction are aligned in the direction of the vertical axis of the wall to form a continuous vertical hole extending over the entire height of the wall, A hole having a diameter commensurate with the diameter of the rod so that the hole can be inserted into a continuous hole extending over the entire height of the wall,
The length of the rod is greater than or equal to the height of the wall, and the rod is inserted vertically so that it passes through the continuous vertical holes described in i and j,
The creation of a proof link between vertically and horizontally adjacent bricks creates a wall that allows the insertion of a skeleton consisting of multiple rods, resulting in high lateral stiffness and extreme A system is provided that results in a structure with uniform force, periodic force, and high resistance to gravity forces. The brick and rod system according to the invention also provides a flexible connection for constructing walls with seismic motion or earthquake resistance.

  In another aspect, the present invention provides a rounded convex geometric symmetrical protrusion provided on one of the sides of a brick, wherein the protrusion is horizontally adjacent to the brick. e Protrusions that are precisely connected to the cavity described in e, with the base of the protrusion on the side defined in the same direction of the X axis being shorter than the maximum diameter of the convex geometry of the protrusion And provide bricks.

  In another aspect, the present invention provides a rounded convex geometric symmetrical protrusion provided on one of the sides of a brick, wherein the protrusion is horizontally adjacent to the brick. e is precisely connected to the cavity described, and the base of the protrusion on the vertical side defined in the same direction of the X-axis is shorter than the maximum diameter of the convex geometry of the protrusion, Characterized by a protrusion whose length in the Z-axis direction defined by the top of the convex geometry of the base to the base on the side of the brick is between 26% and 65% of the width Z of the brick To provide bricks.

  In another aspect, the present invention provides a brick characterized by a 90 degree right angle groove in the Y-axis direction at the two edges of the front vertical plane and a 90 degree right angle groove in the X axis direction at the two edges of the lower horizontal plane. provide.

  In one additional aspect, the invention provides a 90 degree right angle groove in the Y-axis direction at the two edges of the front vertical plane, a 90 degree right angle groove in the Y axis direction at the two edges of the rear vertical surface, and an upper horizontal plane. Provided is a brick characterized by a 90 degree right angle groove in the X axis direction at the two edges and a 90 degree right angle in the X axis direction at the two edges of the lower horizontal plane.

One additional aspect of the present invention is:
i. A pipe having a length equal to the height of the brick, the pipe functions as an internal thread, the pipe has an internal thread, and the screw described in ii is screwed therein When,
ii. a male thread having a length equal to or less than the length of the pipe described in i, wherein the male thread has an external thread, the upper half of which is fitted into the pipe as described in i, and the lower half of the pipe is i. An assembly rod comprising a male thread that fits into another pipe as described and is joined to two pipes that are inserted into two vertically adjacent bricks by a mating joint formed;
A plurality of tubes and a plurality of male threads form a continuous assembly rod to provide an assembly rod constructed.

  In another additional aspect, the present invention provides an assembly rod comprising rod pieces each having a length that is one and a half times the height of the brick (1.5 times), wherein each rod piece is It is formed by three parts defined as a first part, a second part, and a third part, and the three parts are exactly the same length, and each part is 3 times the length of the rod piece. Has a length equal to one part, the first part is one end of the rod piece, the first part is hollow and has an internal thread, thereby constituting a part that functions as an internal thread of the rod piece The second part is in the middle of the rod piece between the first part and the third part, the second part is solid, the third part is solid and externally threaded The third part is at the opposite end of the first part and the third part is the male part of the rod piece. The first part of the rod part piece is screwed to the third part of another same rod part piece, and an assembly rod is formed by a plurality of the same rod part pieces screwed together. An assembly rod is provided.

  In one additional aspect, the present invention provides a symmetrical protrusion having a rounded convex geometric shape in the X-axis provided in the center of the front vertical surface of the brick, the protrusion being e The maximum diameter of the protruding geometric shape of the protruding portion is the base of the protruding portion on the front vertical plane of the brick, which is accurately connected to the horizontally adjacent bricks by the hollow portion described in 1. The length of the protrusion in the X-axis direction defined by the top of the convex geometry of the protrusion to the base on the front vertical surface of the brick is from 26% of the width Z of the brick. Provide bricks characterized by protrusions that are between up to 65%.

  Another additional aspect of the present invention is a symmetric cavity with a rounded concave geometric shape in the center of the rear vertical plane of the brick, wherein the cavity is d. The cavity opening on the rear vertical surface of the brick defined in the same direction of the Z axis is shorter than the maximum diameter of the concave geometry of the cavity, Characterized by a cavity whose X-axis cavity length defined by the top of the concave geometry from the opening on the rear vertical plane of the brick is between 26% and 65% of the width Z of the brick And provide bricks.

  In another additional aspect, the present invention provides two protrusions of a Y-axis cylindrical convex geometry disposed symmetrically in the center of the upper horizontal surface of the brick, the protrusions being The hollow portion described in g) is accurately connected to a vertically adjacent block, and the diameter of the base of each protrusion on the upper horizontal surface of the brick is equal to or greater than the diameter of the cylindrical portion of the protrusion. A brick characterized by a protrusion whose length in the Y-axis direction from the top of the geometric shape to the base on the upper horizontal surface of the brick is between 26% and 65% of the width Z of the brick To do.

  In another additional aspect, the present invention provides two cavities of cylindrical concave geometry in the Y-axis direction symmetrically disposed in the center of the lower horizontal plane of the brick, the cavities being f Are accurately connected to the vertically adjacent blocks by the protrusions described in 1., and the diameter of the opening of each cavity on the lower horizontal plane of the brick is equal to or greater than the diameter of the cylindrical part of the cavity, and the concave geometry of the cavity Characterized by a cavity where the length of the cavity in the Y-axis defined by the top of the geometric shape to the opening of the cavity on the lower horizontal plane of the brick is between 26% and 65% of the width Z of the brick To provide bricks.

In yet another aspect, the present invention provides two vertical cylindrical holes penetrating the brick, the length of the hole in the Y-axis direction being the convex geometric shape of the protrusion described in f. The direction of the vertical axis of the wall is defined by the top of the concave geometry of the cavity described in g from the top, and these two holes and the same hole in the wall vertically adjacent to the brick To form a continuous vertical hole extending over the entire height of the wall, the diameter of the two holes being commensurate with the diameter of the rod,
A brick is provided wherein the length of the rod is equal to or greater than the height of the wall, and the hole is inserted vertically so that the rod penetrates a continuous vertical hole in the wall.

  Objects and additional advantages of the present invention will become more apparent from the description of the drawings, the best mode for carrying out the invention, and the claims.

1 is a three-dimensional view of a brick and rod system according to an embodiment of the present invention. FIG. It is a three-dimensional view of a rod piece. It is a three-dimensional view of a rod piece. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 2 is a two-dimensional view of an upper horizontal surface of a brick according to an embodiment of the present invention. FIG. FIG. 2 is a two-dimensional view showing one of the vertical sides of a brick according to an embodiment of the invention. It is a two-dimensional view of the sagittal plane that cuts the central portion in the Z-axis direction through one of the holes penetrating the brick according to one embodiment of the present invention. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 2 is a two-dimensional view of an upper horizontal surface of a brick according to an embodiment of the present invention. FIG. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 2 is a two-dimensional view of an upper horizontal surface of a brick according to an embodiment of the present invention. FIG. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. It is the two-dimensional figure which looked at the wall body constructed | assembled with the brick by one Embodiment of this invention from the side surface. It is the two-dimensional view which looked at the wall body constructed | assembled with the some brick and the some rod by one Embodiment of this invention from the side surface. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 2 is a two-dimensional view of an upper horizontal surface of a brick according to two embodiments of the present invention. FIG. FIG. 6 is a two-dimensional view of a plane extending from a protrusion and a vertical cavity and cutting in the Z-axis direction through one of the holes vertically penetrating a brick according to an embodiment of the present invention. FIG. 2 is a two-dimensional view showing one of the vertical sides of a brick according to an embodiment of the invention. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 2 is a two-dimensional view of an upper horizontal surface of a brick according to two embodiments of the present invention. FIG. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 2 is a two-dimensional view of an upper horizontal surface of a brick according to two embodiments of the present invention. FIG. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 2 is a two-dimensional view of an upper horizontal surface of a brick according to an embodiment of the present invention. FIG. It is the two-dimensional figure which looked at the wall body constructed | assembled with the brick by one Embodiment of this invention from the side surface. It is the two-dimensional view which looked at the wall body constructed | assembled with the some brick and the some rod by one Embodiment of this invention from the side surface. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 1 is a three-dimensional view of a brick according to an embodiment of the present invention. 1 is a three-dimensional view of a brick according to an embodiment of the present invention.

  FIG. 1 shows a three-dimensional view of a brick according to one embodiment and rods (4), (5A) and (5B) according to two embodiments inserted into the brick. 2A and 2B show two embodiments of rod pieces that mate with other rod pieces to form an assembled rod. As shown in FIG. 7, a brick is defined by three orthogonal coordinates X, Y, and Z, of which a horizontal axis X defines a length, a vertical axis Y defines a height, and a horizontal axis Z has a width. Is specified.

  Figures 5 and 6 show that the brick has an upper horizontal surface (6) and a lower horizontal surface (13).

  In FIGS. 3, 4 and 5, the front vertical surface (7) and the rear vertical surface (8) of the brick are shown.

  In FIGS. 4 and 6 two vertical sides (14) of the brick can be seen.

  3 and 4 show a symmetrical protrusion (1) with a rounded convex geometric shape provided in the center of the front vertical surface (7) of the brick, the rear vertical surface of the brick ( An embodiment of a brick is shown comprising the protrusion (1) which is precisely connected to a horizontally adjacent brick by means of a symmetrical cavity (2) of concave geometry provided in the center of 8). . FIG. 4 shows that the length of the base (9) of the protrusion on the front vertical surface (7) of the brick is shorter than the maximum diameter (10) of the convex geometry of the protrusion. Has been. FIG. 4 also shows that the length of the cavity opening (11) on the rear vertical plane of the brick is less than the maximum diameter (12) of the concave geometry of the cavity.

  3, 4, 5 and 6 show two protrusions (3) of cylindrical convex geometry arranged symmetrically in the center of the upper horizontal surface of the brick. The protrusion (3) is precisely connected to the vertically adjacent block by a cylindrical concave geometry cavity (16) (FIG. 5) arranged symmetrically in the center of the lower horizontal plane (13). To do. It can be seen from FIG. 6 that the diameter (18) of the base of each protrusion on the upper horizontal surface of the brick is greater than the diameter of the cylindrical part (17) of the protrusion (3). Similarly, it can be seen from FIG. 5 that the diameter (19) of the opening of each cavity on the lower horizontal surface (13) of the brick is greater than or equal to the diameter of the cylindrical portion (20) of the cavity (16).

  FIGS. 1 to 8 show two vertical cylindrical holes (15) that penetrate the brick, the length of which is the top of the convex geometry of the protrusion (3). (21) (FIG. 5) to the top (22) (FIG. 5) of the concave geometry of the cavity (16).

  From FIG. 12, the hole (15) and the hole (15) identical to that of the vertically adjacent brick in the wall are centered in the direction of the vertical axis of the wall, thereby extending over the entire height of the wall. It can be seen that continuous vertical holes are formed.

  FIGS. 3 to 12 show one vertical cylindrical hole (23) penetrating the brick, the length of which varies from the upper horizontal plane (6) of the brick to the lower horizontal plane (13) of the brick. ). The hole (23) is arranged in parallel between the two holes (15).

  In FIGS. 3-5, 7, 8, and 12, a vertical cylindrical hole (24) is shown through the protrusion (1). The length of the hole (24) is defined by the center of the upper horizontal surface of the protrusion (1) to the center of the lower horizontal surface of the protrusion (1).

  From FIG. 12, a hole (23) and a vertically adjacent brick of the same diameter (24) of the same diameter are aligned in the direction of the vertical axis of the wall, thereby extending a continuous vertical extending over the entire height of the wall. It can be seen that a simple hole is formed. In FIG. 13 the rods (4), (5), (26) or (so that the diameter of the holes (23) and (24) can be inserted into a continuous hole extending over the entire height of the wall. 27) It can be seen that it is commensurate with the diameter of (Figs. 1 and 2).

  It can be seen from FIG. 13 that the length of the rod is greater than or equal to the height of the wall. Further, it can be seen that the rod is inserted vertically so that the holes (23) and (24) (FIGS. 12 and 13) penetrate through a continuous vertical hole.

  7 and 8 show another embodiment of a brick according to the present invention. In this embodiment, the brick does not have a cavity (2), but a brick with a flat rear vertical surface (8). This brick is the leading brick in the horizontal row of bricks.

  9 and 10 show another embodiment of a brick according to the present invention. In this embodiment, the brick does not have a protrusion (1), but a brick with a flat front vertical surface (7). This brick will be the last brick in the horizontal row of bricks.

  FIG. 11 shows another embodiment of a brick according to the present invention. This embodiment shows a brick characterized by symmetrical protrusions (28) of rounded convex geometry provided on one of the brick sides (14). The protrusions are accurately connected to the horizontally adjacent brick cavity (2).

  From FIG. 23, it can be seen that the base (29) of the protrusion on the side is shorter than the maximum diameter (30) of the convex geometry of the protrusion (28).

  The brick and rod system described herein forms a proof connection between vertically and horizontally adjacent bricks to build a wall capable of inserting a skeleton consisting of multiple rods. This results in a structure with high lateral stiffness and high resistance to extreme uniform forces, periodic forces and gravity forces.

  Further, a rounded convex horizontal protrusion (1), a rounded concave horizontal cavity (2), a rounded cylindrical convex vertical protrusion (3), and The brick and rod system according to the invention with a rounded cylindrical concave vertical cavity (16) forms a flexible connection for the construction of walls that are not prone to cracking during earthquake motion or earthquakes. Enable.

14 to 21 are other embodiments according to the present invention, in which the brick is
a. Symmetrical protrusion (1) with a rounded convex geometry provided in the center of the front vertical surface (7) of the brick, the top of the convex geometry of the protrusion (1) ( 33) to the length (31) (FIGS. 15 and 19) of the protrusion (1) defined by the base (32) of the front vertical surface (7) of the brick is 26% to 65% of the width Z of the brick A protrusion (1) that is between,
b. A symmetric cavity (2) of concave geometry provided in the middle of the rear vertical surface (8) of the brick, from the top (35) of the concave geometry of the cavity (2) to the rear of the brick A cavity whose length (34) (FIGS. 15 and 21) of the cavity (2) defined by the opening (36) on the vertical plane (8) is between 26% and 65% of the width Z of the brick Part (2),
c. Two protrusions (3) of cylindrical convex geometry arranged symmetrically in the center of the upper horizontal surface (6) of the brick, the top of the convex geometry of the protrusion (3) ( The length (37) (FIG. 16) of the protrusion (3) defined by 21) to the base (38) on the upper horizontal surface (6) of the brick is between 26% and 65% of the width Z of the brick A protrusion (3) which is
d. Two cavities (16) of cylindrical concave geometry arranged symmetrically in the center of the lower horizontal surface (13) of the brick, the top (22) of the concave geometry of the cavity (16) The length (39) (FIG. 16) of the cavity (16) defined by the opening (40) of the cavity (16) on the lower horizontal surface (13) of the brick is from 26% to 65 of the width Z of the brick. FIG. 3 shows an embodiment with a cavity (16) that is between up to%.

  Figures 22 and 23 are another embodiment of a brick having a symmetric protrusion (28) of rounded convex geometry provided on one of the brick sides (14). The length (41) of the protrusion (28) defined by the top (42) of the convex geometry of the protrusion (28) to the base (29) on the side (14) of the brick (FIG. 22) Shows an embodiment in which is between 26% and 65% of the width Z of the brick.

  24 and 25 are bricks with two vertical cylindrical holes (15) penetrating the bricks, identical to those of the bricks (15) and vertically adjacent bricks in the wall A brick whose hole (15) is centered in the direction of the vertical axis of the wall, thereby forming a continuous vertical hole extending over the entire height of the wall, and whose hole diameter matches the diameter of the rod The embodiment of this invention characterized by these is shown. FIG. 25 shows that the length of the rod is equal to or greater than the height of the wall. From the same FIG. 25 it can be seen that the rod can be inserted into a continuous hole extending over the entire height of the wall.

  The continuous holes in the wall shown in FIG. 24 can also be used to pass electrical cables, gas pipes, telephone cables, etc. vertically through the wall.

  FIG. 26 shows another embodiment of a brick according to the present invention. In this embodiment, the brick is 90 degrees perpendicular to the Y axis in the two edges (44) of the front vertical plane (7) and 90 degrees perpendicular to the Y axis in the two edges (45) of the rear vertical plane. And 90 degrees perpendicular to the X axis direction at the two edges (46) of the upper horizontal plane and 90 degrees perpendicular to the X axis direction at the two edges (43) of the lower horizontal plane.

  FIG. 27 shows another embodiment of a brick according to the present invention. In this embodiment, the brick is characterized by a 90 degree right angle in the Y axis direction at the two edges (47) of the front vertical plane and a 90 degree right angle in the X axis direction at the two edges (48) of the lower horizontal plane. .

  28 and 29 are other embodiments of the brick according to the present invention, in which the brick is relative to other adjacent bricks so that they are arranged horizontally at the beginning or end of the horizontal row of bricks. Shown is an embodiment that realizes a wall with a continuous vertical edge by creating a flat edge between other horizontal bricks that are half length in the X-axis direction and vertically adjacent Yes.

  The rod according to the invention can be a rod (5) consisting of a single part or an assembled rod consisting of sequentially connected rod pieces.

  The rod piece can be seen in FIG. 1, which shows a tube (5A) whose length is equal to the height of the brick, where the tube functions as an internal thread and whose tube has an internal thread A tube adapted to be screwed onto a male screw (5B) with The male screw (5B) has a length equal to or shorter than the length of the tube (5A). The male thread is connected to the inside of the pipe (5A) by its upper half and connected to another pipe (5A) by its lower half, thereby forming a connection of two pipes inserted into two vertically adjacent bricks. . The continuous assembly rod is constituted by a series of connections formed by a plurality of tubes (5A) and a plurality of male threads (5B).

  In another embodiment of the invention, the assembly rod is provided by rod pieces (26) and (27) (FIGS. 2A and 2B) that are one and a half times (1.5 times) the height of the brick. Composed. Each of the rod pieces (26) and (27) is formed by three parts defined as a first part (49), a second part (50) and a third part (51), The three parts are exactly the same length, each part has a length equal to one third of the length of the rod piece, and the first part (49) is at one end of the rod piece. The first part is hollow and has an internal thread that constitutes a part that functions as a female thread of the rod piece, and the second part (50) is formed by the first part (49) and the third part (51). In the middle of the rod piece in between, the second part (50) is solid, the third part (51) is solid and has external threads, and the third part (51) is the first part The third portion (51) is a portion that functions as a male screw of the rod piece, at the end opposite to one end constituting the portion (49). An assembly rod by connecting a first part (49) of a rod piece with a third part (51) of another identical rod piece and thus connecting a plurality of rod pieces in sequence Is formed.

  One of the advantages of the present invention is a reduction in the use of mortar or adhesive between horizontally and vertically adjacent bricks in the construction of the wall. This is between a convex geometry symmetrical protrusion (1) and a concave geometry symmetrical cavity (2) that form a perfect complementarity between horizontally adjacent bricks, and This is achieved by the connection between the cylindrical convex protrusion (3) and the cylindrical concave cavity (16) in perfect complementarity between vertically adjacent bricks.

  However, another embodiment of the present invention is a brick having a cylindrical convex protrusion (3) provided on the upper horizontal surface (6), the cylindrical portion being the upper horizontal surface (6). Forming an angle (52) (FIG. 16) with a slightly rounded transition between them, while a cylindrical concave cavity (16) is provided in the lower horizontal plane (13), the cylindrical part of which Comprises bricks forming a 90 degree right angle (53) (FIG. 16) with the lower horizontal plane (13). The deviation between the angle (52) formed by the protrusion (1) and the angle (53) formed by the cavity (16) creates an incomplete connection between the vertically adjacent bricks, which Creates a gap in millimeters between vertically adjacent bricks. Such gaps may be required by seismic rules. If necessary, such gaps can be filled with mortar.

  Although the preferred embodiment of the present invention has been described in the description, further changes can be made to the shape and arrangement of each part without departing from the basic idea and principle contained in the following claims.

DESCRIPTION OF SYMBOLS 1 Horizontal protrusion part 2 Horizontal cavity part 3 Vertical protrusion part 4 Rod 5 Rod 5A Pipe 5B Male screw 6 Upper horizontal surface 7 Front vertical surface 8 Rear vertical surface 9 Base 10 Maximum diameter 11 Opening 13 Lower horizontal surface 14 Side surface 15 Hole 16 Cavity Part 17 Cylindrical part 18 Diameter 19 Diameter of opening 20 Cylindrical part 21 Top part 22 Top part 23 Hole 24 Hole 26 Rod part piece 27 Rod part piece 28 Projection part 29 Base part 30 Maximum diameter 31 Length 32 Base part 33 Top part 34 Length 35 Top 36 Opening 37 Length 38 Base 39 Length 40 Opening 41 Length 42 Top 43 Edge 44 Edge 45 Edge 46 Edge 47 Edge 48 Edge 49 First part 50 Second part 51 Third part 52 Angle 53 Angle

Claims (21)

A brick and rod system, defined by three orthogonal coordinates X, Y, Z, a horizontal axis X defining length, a vertical axis Y defining height, and a horizontal axis Z defining width Characterized by a three-dimensional rectangular brick for building a wall and a rod,
a. An upper horizontal plane and a lower horizontal plane defined by the X axis and the Z axis;
b. A front vertical plane and a rear vertical plane defined by the Z-axis and the Y-axis;
c. Two vertical sides defined by the X and Y axes;
d. A symmetrical protrusion of a rounded convex geometric shape provided in the center of the front vertical surface of the brick, wherein the protrusion is horizontally formed by the cavity described in e. The length of the base of the protrusion on the front vertical surface of the brick defined in the same direction of the Z axis is shorter than the maximum diameter of the convex geometry of the protrusion exactly connected to adjacent blocks A protrusion that is
e. A symmetric hollow portion of a concave geometric shape in the X-axis direction provided in the center of the rear vertical surface of the brick, wherein the hollow portion is horizontally adjacent by the protrusion described in d. A cavity that is precisely connected and has an opening length of the cavity on the back vertical plane of the brick defined in the same direction as the Z-axis that is shorter than the maximum diameter of the concave geometry of the cavity;
f. Two protrusions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the upper horizontal surface of the brick, wherein the protrusions are vertically adjacent by a cavity described in g A projection that is precisely connected to the block to be constructed, and wherein the diameter of the base of each projection on the upper horizontal surface of the brick is equal to or greater than the diameter of the cylindrical portion of the projection;
g. Two hollow portions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the lower horizontal surface of the brick, wherein the hollow portions are vertically aligned by the protrusions described in f. A cavity that is precisely connected to an adjacent block, and wherein the diameter of the opening of each cavity on the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the cavity;
h. Two vertical cylindrical holes penetrating the brick, wherein the length of the hole in the Y-axis direction is from the top of the convex geometric shape of the protrusion described in f to the cavity described in g Of the wall body by aligning the hole and the same hole in the brick vertically adjacent to the wall body in the direction of the vertical axis of the wall body. A hole forming a continuous vertical hole extending over the entire height;
i. A vertical cylindrical hole penetrating the brick, the length of the hole in the Y-axis direction being defined by the upper horizontal surface of the brick to the lower horizontal surface of the brick, the hole being h By arranging in parallel between the two holes described above, and the hole of the same diameter described in j of the brick adjacent to the vertical direction in the direction of the vertical axis of the wall A continuous vertical hole is formed extending over the entire height of the wall, and the hole has a diameter commensurate with the diameter of the rod so that a rod can be inserted into the continuous hole extending over the entire height of the wall. With holes,
j. a vertical cylindrical hole penetrating the protruding portion described in d in the Y-axis direction, wherein the length of the hole extends from the center of the upper horizontal surface of the protruding portion to the center of the lower horizontal surface of the protruding portion. This hole and a hole of the same diameter described in i of a brick adjacent to the vertical direction are aligned in the direction of the vertical axis of the wall, thereby extending a continuous vertical extending over the entire height of the wall. A solid block comprising a hole formed, the hole having a diameter commensurate with the diameter of the rod so that the rod can be inserted into the continuous hole extending across the entire height of the wall;
The length of the rod is equal to or greater than the height of the wall, and the rod is inserted vertically so as to penetrate the continuous vertical holes described in i and j;
By creating a proof link between vertically and horizontally adjacent bricks, a wall is constructed that allows the insertion of a skeleton consisting of a plurality of said rods, thereby providing high lateral stiffness, A system that results in a structure with extreme uniform forces, periodic forces, and high resistance to gravity forces.   The brick is a symmetrical protrusion having a rounded convex geometric shape provided on one of the vertical side surfaces of the brick, wherein the protrusion is a horizontally adjacent brick. The length of the base of the protrusion on the vertical side defined in the same direction of the X axis is shorter than the maximum diameter of the convex geometric shape of the protrusion. The system according to claim 1, characterized by a protrusion that is thick.   2. The brick according to claim 1, wherein the brick has 90-degree right-angle grooves in the Y-axis direction at two edges of the front vertical surface and 90-degree right-angle grooves in the X-axis direction at two edges of the lower horizontal plane. System.   The bricks are 90 degree right angle grooves in the Y-axis direction at two edges of the front vertical surface, 90 degree right angle grooves in the Y axis direction at two edges of the rear vertical surface, and two edges of the upper horizontal surface. The system according to claim 1, characterized by a 90 degree right angle groove in the X axis direction and a 90 degree right angle in the X axis direction at two edges of the lower horizontal plane. The rod is
a. A pipe having a length equal to the height of the brick, wherein the pipe functions as an internal thread, the pipe has an internal thread, and the screw described in b is screwed therein. A tube with
b. a male screw having a length equal to or shorter than the length of the tube described in a, wherein the male screw has an external screw, and the male screw fits into the tube as described in a in its upper half, and in the lower half an assembly rod comprising a male thread that fits into another pipe as described in a and is joined to two pipes that are inserted into two vertically adjacent bricks by a fitting joint formed ,
The system of claim 1, wherein a continuous assembly rod is formed and configured by the plurality of tubes and the plurality of male threads.   The rod is an assembly rod that includes rod pieces each having a length that is one and a half times (1.5 times) the height of the brick, each rod piece being a first portion, a second portion. And three parts defined as a third part, the three parts being exactly the same length, each part being equal to one-third of the length of the rod piece The first part is one end of the rod part piece, the first part is hollow and has an internal thread, thereby constituting a part that functions as an internal thread of the rod part piece The second part is intermediate the rod piece between the first part and the third part, the second part is solid and the third part is solid. Having an external thread, the third part is at the opposite end of the first part; The third part is a part that functions as a male screw of the rod part piece, and the first part of the rod part piece is screwed to the third part of another identical rod part piece, and is sequentially screwed. The system of claim 1, wherein the assembly rod is formed by a plurality of identical rod pieces joined together. A brick and rod system, defined by three orthogonal coordinates X, Y, Z, a horizontal axis X defining length, a vertical axis Y defining height, and a horizontal axis Z defining width Characterized by a three-dimensional rectangular brick for building a wall and a rod,
a. An upper horizontal plane and a lower horizontal plane defined by the X axis and the Z axis;
b. A front vertical plane and a rear vertical plane defined by the Z-axis and the Y-axis;
c. Two vertical sides defined by the X and Y axes;
d. A symmetrical protrusion of a rounded convex geometric shape provided in the center of the front vertical surface of the brick, wherein the protrusion is horizontally formed by the cavity described in e. The length of the base of the protrusion on the front vertical surface of the brick defined in the same direction of the Z axis is shorter than the maximum diameter of the convex geometry of the protrusion exactly connected to adjacent blocks A protrusion that is
e. A symmetric hollow portion of a concave geometric shape in the X-axis direction provided in the center of the rear vertical surface of the brick, wherein the hollow portion is horizontally adjacent by the protrusion described in d. A cavity that is precisely connected and has an opening length of the cavity on the back vertical plane of the brick defined in the same direction as the Z-axis that is shorter than the maximum diameter of the concave geometry of the cavity;
f. Two protrusions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the upper horizontal surface of the brick, wherein the protrusions are vertically adjacent by a cavity described in g A projection that is precisely connected to the block to be constructed, and wherein the diameter of the base of each projection on the upper horizontal surface of the brick is equal to or greater than the diameter of the cylindrical portion of the projection;
g. Two hollow portions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the lower horizontal surface of the brick, wherein the hollow portions are vertically aligned by the protrusions described in f. A cavity that is precisely connected to an adjacent block, and wherein the diameter of the opening of each cavity on the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the cavity;
h. Two vertical cylindrical holes penetrating the brick, wherein the length of the hole in the Y-axis direction is from the top of the convex geometric shape of the protrusion described in f to the cavity described in g Of the wall body by aligning the hole and the same hole in the brick vertically adjacent to the wall body in the direction of the vertical axis of the wall body. A solid block comprising a continuous vertical hole extending over the entire height, the diameter of the two holes being commensurate with the diameter of the rod;
The length of the rod is equal to or greater than the height of the wall, and the rod is inserted vertically so as to penetrate the continuous vertical hole in the wall;
By creating a proof link between vertically and horizontally adjacent bricks, a wall is constructed that allows the insertion of a skeleton consisting of a plurality of said rods, thereby providing high lateral stiffness, A system that results in a structure with extreme uniform forces, periodic forces, and high resistance to gravity forces.   The brick is a symmetrical protrusion having a rounded convex geometric shape provided on one of the vertical sides of the brick, wherein the protrusion is a horizontally adjacent brick. The length of the base of the protrusion on the side surface that is accurately connected to the cavity described in e of the above and defined in the same direction of the X axis is shorter than the maximum diameter of the convex geometric shape of the protrusion The system of claim 7, characterized by a protrusion that is   8. The brick according to claim 7, wherein the brick has a 90-degree right-angle groove in the Y-axis direction at two edges of the front vertical surface and a 90-degree right-angle groove in the X-axis direction at two edges of the lower horizontal plane. System.   The bricks are 90 degree right angle grooves in the Y-axis direction at two edges of the front vertical surface, 90 degree right angle grooves in the Y axis direction at two edges of the rear vertical surface, and two edges of the upper horizontal surface. The system according to claim 7, characterized by a 90 degree right angle groove in the X axis direction and a 90 degree right angle in the X axis direction at two edges of the lower horizontal plane. The rod is
a. A pipe having a length equal to the height of the brick, wherein the pipe functions as an internal thread, the pipe has an internal thread, and the screw described in b is screwed therein. A tube with
b. a male screw having a length equal to or shorter than the length of the tube described in a, wherein the male screw has an external screw, and the male screw fits into the tube as described in a in its upper half, and in the lower half an assembly rod comprising a male thread that fits into another pipe as described in a and is joined to two pipes that are inserted into two vertically adjacent bricks by a fitting joint formed ,
The system of claim 7, wherein a continuous assembly rod is formed and configured by the plurality of tubes and the plurality of male threads.   The rod is an assembly rod that includes rod pieces each having a length that is one and a half times (1.5 times) the height of the brick, each rod piece being a first portion, a second portion. And three parts defined as a third part, the three parts being exactly the same length, each part being equal to one-third of the length of the rod piece The first part is one end of the rod part piece, the first part is hollow and has an internal thread, thereby constituting a part that functions as an internal thread of the rod part piece The second part is intermediate the rod piece between the first part and the third part, the second part is solid and the third part is solid. Having an external thread, the third part is at the opposite end of the first part; The third part is a part that functions as a male screw of the rod part piece, and the first part of the rod part piece is screwed to the third part of another identical rod part piece, and is sequentially screwed. The system of claim 7, wherein the assembly rod is formed by a plurality of identical rod pieces joined together. A three-dimensional rectangular brick for building a wall, which has three orthogonal coordinates X, Y, Z, a horizontal axis X that defines a length, a vertical axis Y that defines a height, and a horizontal axis Z that defines a width. Specified by
a. An upper horizontal plane and a lower horizontal plane defined by the X axis and the Z axis;
b. A front vertical plane and a rear vertical plane defined by the Z-axis and the Y-axis;
c. Two vertical sides defined by the X and Y axes;
d. A symmetrical protrusion of a rounded convex geometric shape provided in the center of the front vertical surface of the brick, wherein the protrusion is horizontally formed by the cavity described in e. The length of the base of the protrusion on the front vertical surface of the brick defined in the same direction of the Z axis is shorter than the maximum diameter of the convex geometry of the protrusion exactly connected to adjacent blocks A protrusion that is
e. A symmetric hollow portion of a concave geometric shape in the X-axis direction provided in the center of the rear vertical surface of the brick, wherein the hollow portion is horizontally adjacent by the protrusion described in d. A cavity that is precisely connected and has an opening length of the cavity on the back vertical plane of the brick defined in the same direction as the Z-axis that is shorter than the maximum diameter of the concave geometry of the cavity;
f. Two protrusions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the upper horizontal surface of the brick, wherein the protrusions are vertically adjacent by a cavity described in g A projection that is precisely connected to the block to be constructed, and wherein the diameter of the base of each projection on the upper horizontal surface of the brick is equal to or greater than the diameter of the cylindrical portion of the projection;
g. Two hollow portions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the lower horizontal surface of the brick, wherein the hollow portions are vertically aligned by the protrusions described in f. A cavity that is precisely connected to an adjacent block, and wherein the diameter of the opening of each cavity on the lower horizontal surface of the brick is greater than or equal to the diameter of the cylindrical portion of the cavity;
h. Two vertical cylindrical holes penetrating the brick, wherein the length of the hole in the Y-axis direction is from the top of the convex geometric shape of the protrusion described in f to the cavity described in g Of the wall body by aligning the hole and the same hole in the brick vertically adjacent to the wall body in the direction of the vertical axis of the wall body. A hole forming a continuous vertical hole extending over the entire height;
i. A vertical cylindrical hole penetrating the brick, the length of the hole in the Y-axis direction being defined by the upper horizontal surface of the brick to the lower horizontal surface of the brick, the hole being h By arranging in parallel between the two holes described above, and the hole of the same diameter described in j of the brick adjacent to the vertical direction in the direction of the vertical axis of the wall A continuous vertical hole is formed extending over the entire height of the wall, and the hole has a diameter commensurate with the diameter of the rod so that a rod can be inserted into the continuous hole extending over the entire height of the wall. With holes,
j. a vertical cylindrical hole penetrating the protruding portion described in d in the Y-axis direction, wherein the length of the hole extends from the center of the upper horizontal surface of the protruding portion to the center of the lower horizontal surface of the protruding portion. This hole and a hole of the same diameter described in i of a brick adjacent to the vertical direction are aligned in the direction of the vertical axis of the wall, thereby extending a continuous vertical extending over the entire height of the wall. A solid block comprising a hole, the hole having a diameter commensurate with the diameter of the rod so that the rod can be inserted into the continuous hole extending over the entire height of the wall. Features
The creation of a proof link between vertically and horizontally adjacent bricks creates a wall that allows the insertion of a skeleton consisting of vertical rods, which results in high lateral stiffness and extreme Bricks that result in a structure with uniform force, periodic force, and high resistance to gravity forces.   The rounded convex geometric symmetrical protrusion provided on one of the vertical sides of the brick, wherein the protrusion is a horizontally adjacent brick in claim 13e. A protrusion that is precisely connected to the cavity of the projection and whose base on the vertical side defined in the same direction of the X axis is shorter than the maximum diameter of the convex geometry of the protrusion The brick according to claim 13, characterized by a portion.   The brick according to claim 13, characterized by a 90 degree right angle groove in the Y-axis direction at two edges of the front vertical plane and a 90 degree right angle groove in the X axis direction at two edges of the lower horizontal plane.   90-degree right angle grooves in the Y-axis direction at the two edges of the front vertical surface, 90-degree right angle grooves in the Y-axis direction at the two edges of the rear vertical surface, and X-axis direction grooves at the two edges of the upper horizontal surface. The brick according to claim 13, characterized by a 90 degree right angle groove and a 90 degree right angle in the X-axis direction at two edges of the lower horizontal plane. A three-dimensional rectangular brick for building a wall, which has three orthogonal coordinates X, Y, Z, a horizontal axis X that defines a length, a vertical axis Y that defines a height, and a horizontal axis Z that defines a width. Specified by
a. An upper horizontal plane and a lower horizontal plane defined by the X axis and the Z axis;
b. A front vertical plane and a rear vertical plane defined by the Z-axis and the Y-axis;
c. Two vertical sides defined by the X and Y axes;
d. A symmetrical protrusion of a rounded convex geometric shape provided in the center of the front vertical surface of the brick, wherein the protrusion is horizontally formed by the cavity described in e. The length of the base of the protrusion on the front vertical surface of the brick defined in the same direction of the Z axis is shorter than the maximum diameter of the convex geometry of the protrusion exactly connected to adjacent blocks The length of the protrusion in the X-axis direction defined by the top of the convex geometric shape of the protrusion to the base on the front vertical surface of the brick is 26% of the width Z of the brick. A protrusion that is between 65% and 65%;
e. A symmetric hollow portion of a concave geometric shape in the X-axis direction provided in the center of the rear vertical surface of the brick, wherein the hollow portion is horizontally adjacent by the protrusion described in d. The cavity portion has an opening length on the back vertical plane of the brick that is precisely connected and defined in the same direction as the Z-axis is shorter than a maximum diameter of the concave geometric shape of the cavity portion; A cavity whose length in the X-axis defined by the top of the concave geometry of the brick and the opening on the back vertical plane of the brick is between 26% and 65% of the width Z of the brick And
f. Two protrusions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the upper horizontal surface of the brick, wherein the protrusions are vertically adjacent by a cavity described in g The base of each protrusion on the upper horizontal surface of the brick is not less than the diameter of the cylindrical portion of the protrusion, and the top of the convex geometric shape of the protrusion. The length of the protrusion in the Y-axis direction from the base of the brick to the base on the upper horizontal plane is between 26% and 65% of the width Z of the brick;
g. Two hollow portions of a cylindrical concave geometric shape in the Y-axis direction disposed symmetrically in the center of the lower horizontal surface of the brick, wherein the hollow portions are vertically aligned by the protrusions described in f. Precisely connected to an adjacent block, the diameter of the opening of each cavity on the lower horizontal surface of the brick is equal to or greater than the diameter of the cylindrical portion of the cavity, and the top of the concave geometry of the cavity A cavity whose length in the Y-axis direction defined by the opening of the cavity on the lower horizontal surface of the brick is between 26% and 65% of the width Z of the brick;
h. Two vertical cylindrical holes penetrating the brick, wherein the length of the hole in the Y-axis direction is from the top of the convex geometric shape of the protrusion described in f to the cavity described in g Of the wall body by aligning the hole and the same hole in the brick vertically adjacent to the wall body in the direction of the vertical axis of the wall body. Characterized in that it is a solid block with a hole forming a continuous vertical hole extending over its entire height,
A proof link is created between vertically and horizontally adjacent bricks, which results in high lateral stiffness and high resistance to extreme uniform, periodic and gravity forces Brick to build a wall body with.   18. Two vertical cylindrical holes penetrating the brick, wherein the length of the hole in the Y-axis direction is from the top of the convex geometry of the protrusion according to claim 17f. 17 to the top of the concave geometry of the cavity according to 17 g, wherein the hole and the same hole as that of the brick vertically adjacent to the wall are in the direction of the vertical axis of the wall To form a continuous vertical hole extending over the entire height of the wall so that the same rod can be inserted into the continuous hole extending over the entire height of the wall. A wall having a diameter commensurate with the diameter of the rod and creating a proof link between vertically and horizontally adjacent bricks is constructed to allow insertion of a skeleton composed of vertical rods, That More, a high lateral rigidity, extreme uniform force, periodic force, and wherein a hole leading to structures with a high resistance to the force due to gravity, brick according to claim 17.   The rounded convex geometric symmetrical protrusion provided on one of the vertical sides of the brick, wherein the protrusion is a horizontally adjacent brick of claim 17e. The base of the protrusion on the vertical side of the brick defined in the same direction as the X axis is shorter than the maximum diameter of the convex geometric shape of the protrusion. The length of the protrusion in the Z-axis direction defined by the top of the convex geometry of the protrusion to the base on the side of the brick is 26% to 65% of the width Z of the brick 18. Brick according to claim 17, characterized by protrusions that are between.   The brick according to claim 17, characterized in that a 90 degree right angle groove in the Y-axis direction at two edges of the front vertical plane and a 90 degree right angle groove in the X axis direction at two edges of the lower horizontal plane.   90-degree right angle grooves in the Y-axis direction at the two edges of the front vertical surface, 90-degree right angle grooves in the Y-axis direction at the two edges of the rear vertical surface, and X-axis direction grooves at the two edges of the upper horizontal surface. The brick according to claim 17, characterized by a 90 degree right angle groove and a 90 degree right angle in the X-axis direction at two edges of the lower horizontal plane.

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